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  • Wnt/Tcf1 pathway restricts embryonic stem cell cycle through activation of the Ink4/Arf locus.

Wnt/Tcf1 pathway restricts embryonic stem cell cycle through activation of the Ink4/Arf locus.

PLoS genetics (2017-03-28)
Anchel De Jaime-Soguero, Francesco Aulicino, Gokhan Ertaylan, Anna Griego, Aniello Cerrato, Aravind Tallam, Antonio Del Sol, Maria Pia Cosma, Frederic Lluis
ABSTRACT

Understanding the mechanisms regulating cell cycle, proliferation and potency of pluripotent stem cells guarantees their safe use in the clinic. Embryonic stem cells (ESCs) present a fast cell cycle with a short G1 phase. This is due to the lack of expression of cell cycle inhibitors, which ultimately determines naïve pluripotency by holding back differentiation. The canonical Wnt/β-catenin pathway controls mESC pluripotency via the Wnt-effector Tcf3. However, if the activity of the Wnt/β-catenin controls the cell cycle of mESCs remains unknown. Here we show that the Wnt-effector Tcf1 is recruited to and triggers transcription of the Ink4/Arf tumor suppressor locus. Thereby, the activation of the Wnt pathway, a known mitogenic pathway in somatic tissues, restores G1 phase and drastically reduces proliferation of mESCs without perturbing pluripotency. Tcf1, but not Tcf3, is recruited to a palindromic motif enriched in the promoter of cell cycle repressor genes, such as p15Ink4b, p16Ink4a and p19Arf, which mediate the Wnt-dependent anti-proliferative effect in mESCs. Consistently, ablation of β-catenin or Tcf1 expression impairs Wnt-dependent cell cycle regulation. All together, here we showed that Wnt signaling controls mESC pluripotency and proliferation through non-overlapping functions of distinct Tcf factors.

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BIO, ≥98% (HPLC)